Cs(2)SnI(6)has recently been reported as a promising material to replace Pb-based perovskite materials due to its appropriate optical and electrical properties as well as high stability in the ambient environment. Here, the study focuses on introducing different types of reactants to form highly stable Cs(2)SnI(6)films via a modified two-step process. The structural analysis was examined using the X-ray diffraction measurements and lattice strain and average crystallite size were calculated by the Williamson hall method. All the prepared films showed excellent phase stability at 210 degrees Cwith no major CsI impurity peak. Adding excess I(2)with SnI(4)at 225 degrees Cresulted in inhibiting the decomposition of the film. Raman measurements revealed the presence of three first-order modes at 78, 92, 126 cm(-1), and a higher mode at 248 cm(-1), respectively. The UV-vis results confirm the direct semiconductor nature of Cs(2)SnI(6)with bandgap ranging from 1.31-1.37 eV. The iodine-rich preparation of the films resulted in improved photoluminescence and high hole mobility of 329 (cm(2)V(-1)s(-1)). The present work will provide useful guidance in the preparation protocol of Cs(2)SnI(6)perovskite solar cells.